@article{zhu_yan_li_cheng_li_liu_mao_cho_gao_gao_et al._2024, title={Recent developments of electrospun nanofibers for electrochemical energy storage and conversion}, volume={65}, ISSN={["2405-8289"]}, DOI={10.1016/j.ensm.2023.103111}, abstractNote={Electrochemical energy storage and conversion systems have received remarkable attention during the past decades because of the high demand of the world energy consumption. Various materials along with the structure designs have been utilized to enhance the overall performance. Among them, nanofibers have been widely explored due to their unique properties (i.e., high surface area, multi-functionality, high porosity, outstanding flexibility, etc.) during the past few decades. Meanwhile, electrospinning, considered a simple and low-cost approach, has attracted tremendous attention because those nanofibrous materials with functional properties prepared by this unique technique can address numerous issues, especially in energy fields. This paper aims to comprehensively review the latest advances in developing advanced electrospun nanofibers for electrochemical devices. It starts with a brief introduction to the advantages of the electrospinning technique. It highlights ongoing research activities, followed by the history of electrospinning, the principle of electrospinning, and the uniqueness of electrospun nanofibers. Afterward, state-of-the-art developments for their applications in electrochemical devices, including but not limited to rechargeable batteries, supercapacitors, fuel cells, solar cells, hydrogen storage, etc., are discussed in detail. A future vision regarding challenges and solutions is proposed at the end. This review aims to provide an extensive and comprehensive reference to apply functional electrospun nanofibers in energy areas.}, journal={ENERGY STORAGE MATERIALS}, author={Zhu, Jiadeng and Yan, Chaoyi and Li, Guoqing and Cheng, Hui and Li, Ya and Liu, Tianyi and Mao, Qian and Cho, Hyunjin and Gao, Qiang and Gao, Chunxia and et al.}, year={2024}, month={Feb} }
 @article{jia_dirican_sun_chen_yan_zhu_dong_du_cheng_guo_et al._2019, title={Advanced ZnSnS3@rGO Anode Material for Superior Sodium-Ion and Lithium-Ion Storage with Ultralong Cycle Life}, volume={6}, ISSN={["2196-0216"]}, url={https://publons.com/publon/26924629/}, DOI={10.1002/celc.201801333}, abstractNote={Abstract}, number={4}, journal={CHEMELECTROCHEM}, author={Jia, Hao and Dirican, Mahmut and Sun, Na and Chen, Chen and Yan, Chaoyi and Zhu, Pei and Dong, Xia and Du, Zhuang and Cheng, Hui and Guo, Jiansheng and et al.}, year={2019}, month={Feb}, pages={1183–1191} }
 @article{zhu_yan_zhu_zang_jia_dong_du_zhang_wu_dirican_et al._2019, title={Flexible electrolyte-cathode bilayer framework with stabilized interface for room-temperature all-solid-state lithium-sulfur batteries}, volume={17}, ISSN={["2405-8297"]}, url={https://publons.com/publon/9539991/}, DOI={10.1016/j.ensm.2018.11.009}, abstractNote={Lithium-sulfur batteries (LSBs) are promising next-generation energy storage system beyond state-of-the-art lithium-ion batteries because of their low cost and high energy density. However, liquid electrolyte-based LSBs suffer from “polysulfide shuttle”, and safety concerns originated from the use of flammable organic electrolytes and the formation of lithium dendrites. Herein, we report a novel bilayer framework through integrating a three-dimensional (3D) carbon nanofiber/sulfur (CNF/S) cathode with one-dimensional (1D) ceramic Li0.33La0.557TiO3 (LLTO) nanofiber-poly(ethylene oxide) (PEO) solid composite electrolyte to serve as both cathode and electrolyte for room-temperature ASSLSBs. The stabilized cycling performance of this novel bilayer structure design lies in the reduced interfacial resistance and enhanced electrode/electrolyte interfacial stability due to the addition of Li+ conducting 1D LLTO nanofibers, as well as the formed fast-continuous electron/ion transportation pathways within the 3D cathode architecture. Meanwhile, the mechanically robust bilayer framework with micro-/meso-pores could also accommodate the large volume change of sulfur during continuous charge-discharge process and help suppress the Li dendrite formation. As a result of the aforementioned benefits of the novel bilayer structure design, the introduced ASSLSBs could deliver a stable cycling performance at room temperature with high Coulombic efficiency of over 99%.}, journal={ENERGY STORAGE MATERIALS}, author={Zhu, Pei and Yan, Chaoyi and Zhu, Jiadeng and Zang, Jun and Jia, Hao and Dong, Xia and Du, Zhuang and Zhang, Chunming and Wu, Nianqiang and Dirican, Mahmut and et al.}, year={2019}, month={Feb}, pages={220–225} }
 @article{jia_dirican_sun_chen_zhu_yan_dong_du_guo_karaduman_et al._2019, title={SnS hollow nanofibers as anode materials for sodium-ion batteries with high capacity and ultra-long cycling stability}, volume={55}, ISSN={["1364-548X"]}, url={https://publons.com/publon/2973443/}, DOI={10.1039/c8cc07332e}, abstractNote={In this study, a novel anode material of SnS hollow nanofibers (SnS HNFs) was rationally synthesized by a facile process and demonstrated to be a promising anode candidate for sodium-ion batteries.}, number={4}, journal={CHEMICAL COMMUNICATIONS}, author={Jia, Hao and Dirican, Mahmut and Sun, Na and Chen, Chen and Zhu, Pei and Yan, Chaoyi and Dong, Xia and Du, Zhuang and Guo, Jiansheng and Karaduman, Yekta and et al.}, year={2019}, month={Jan}, pages={505–508} }
 @article{jia_dirican_chen_zhu_yan_dong_du_guo_wang_tang_et al._2018, title={Carbon-coated CoS@rGO anode material with enhanced cyclic stability for sodium storage}, volume={233}, ISSN={["1873-4979"]}, url={https://publons.com/publon/26924642/}, DOI={10.1016/j.matlet.2018.08.150}, abstractNote={Carbon-coated cobalt [email protected] graphene oxide ([email protected]@C) composite was innovatively synthesized by a simple solvothermal reaction and subsequent carbon coating process for use as the anode material in sodium-ion batteries (SIBs). In this composite structure, the rGO network and extra outer carbon coating worked synergically to achieve excellent electrode architecture stability upon long-term cycling. Specifically, the [email protected]@C composite anode demonstrated superior reversible capacity (706 mAh·g−1 at 100 mA·g−1 at the 1st cycle), high rate capability (374 mAh·g−1 at 1.6 A·g−1), and remarkably stable cycling performance (80% capacity preservation for up to 100 cycles) based on the synergistic action of rGO and carbon coating on CoS. In addition to improving the electrochemical performance of CoS anodes, this composite material strategy can be conveniently adapted to other metal-based anode designs to improve their cycling stability and promote their application in energy storage.}, journal={MATERIALS LETTERS}, author={Jia, Hao and Dirican, Mahmut and Chen, Chen and Zhu, Pei and Yan, Chaoyi and Dong, Xia and Du, Zhuang and Guo, Jiansheng and Wang, Jiasheng and Tang, Fangcheng and et al.}, year={2018}, month={Dec}, pages={158–161} }
 @article{gong_meng_he_dong_2018, title={Fabrication of highly conductive and multifunctional polyester fabrics by spray-coating with PEDOT:PSS solutions}, volume={121}, ISSN={["0300-9440"]}, DOI={10.1016/j.porgcoat.2018.04.006}, abstractNote={In this work, highly conductive and multifunctional polyester fabrics (PET fabrics) were fabricated through repeating the spray-coating process, using poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) solutions containing 5 wt% dimethyl sulfoxide (DMSO). The effects of the coating amount on the conductivity and surface morphologies were investigated. The electrochemical properties were evaluated by cyclic voltammetry (CV) and the heat performance was also investigated. Moreover, the breaking strength, rubbing and washing fastness were measured as well. Results indicate that the minimum sheet resistance is 12.10 Ω/□ when the weight gain rate is 23.4%. The enhancement of the conductivity can attribute to the improvement of uniformity, thickness, connectivity and the emergence of PEDOT microcrystals of the multiply coatings, which mean better pathways for conduction. The maximum mass-specific capacitance of the coated fabric can achieve to 75.30 F/g at the scan rate of 20 mV/s. Good fidelity and no degradation of the repeated CV curves indicates the excellent electrochemical stability. The coated fabric can be heated to 56.2 °C in 100 s under the applied voltage of 7 V. The temperature distribution of the coated fabric is quite uniform, demonstrating the homogeneity of the PEDOT:PSS coating. The increase of the sheet resistance is not significant after rubbing and washing, which illustrates good rubbing and washing fastness.}, journal={PROGRESS IN ORGANIC COATINGS}, author={Gong, Fen and Meng, Chen and He, Jinxin and Dong, Xia}, year={2018}, month={Aug}, pages={89–96} }
 @article{jia_dirican_chen_zhu_zhu_yan_li_dong_guo_zhang_et al._2018, title={Reduced Graphene Oxide-Incorporated SnSb@CNF Composites as Anodes for High-Performance Sodium-Ion Batteries}, volume={10}, ISSN={["1944-8244"]}, url={https://doi.org/10.1021/acsami.7b18921}, DOI={10.1021/acsami.7b18921}, abstractNote={Sodium-ion batteries (SIBs) are promising alternatives to lithium-ion batteries because of the low cost and natural abundance of sodium resources. Nevertheless, low energy density and poor cycling stability of current SIBs unfavorably hinder their practical implementation for the smart power grid and stationary storage applications. Antimony tin (SnSb) is one of the most promising anode materials for next-generation SIBs attributing to its high capacity, high abundance, and low toxicity. However, the practical application of SnSb anodes in SIBs is currently restricted because of their large volume changes during cycling, which result in serious pulverization and loss of electrical contact between the active material and the carbon conductor. Herein, we apply reduced graphene oxide (rGO)-incorporated SnSb@carbon nanofiber (SnSb@rGO@CNF) composite anodes in SIBs that can sustain their structural stability during prolonged charge-discharge cycles. Electrochemical performance results shed light on that the combination of rGO, CNF, and SnSb alloy led to a high-capacity anode (capacity of 490 mAh g-1  at the 10th cycle) with a high capacity retention of 87.2% and a large Coulombic efficiency of 97.9% at the 200th cycle. This work demonstrates that the SnSb@rGO@CNF composite is a potential and attractive anode material for next-generation, high-energy SIBs.}, number={11}, journal={ACS APPLIED MATERIALS & INTERFACES}, publisher={American Chemical Society (ACS)}, author={Jia, Hao and Dirican, Mahmut and Chen, Chen and Zhu, Jiadeng and Zhu, Pei and Yan, Chaoyi and Li, Ya and Dong, Xia and Guo, Jiansheng and Zhang, Xiangwu and et al.}, year={2018}, month={Mar}, pages={9696–9703} }